#include "device_type.h"
#ifdef SM_PIR

#include "app_api.h"
#include "app_log.h"
#include "app_cli_cmd.h"
#include "bsp_gpio.h"
#include "app_button.h"
#include "app_led.h"
#include "bsp_iadc.h"
#include "em_emu.h"
#include "softwareMultiTimer.h"
#include "device.h"
#include "bsp_system.h"
#include "net_protocol.h"
#include "app_key_value.h"
#include "bsp_rmu.h"
#include "bsp_wdog.h"
#include "RBFVersion.h"
#include "git_version.h"
#include "net_aseq.h"

#define DEVICE_TX_POWER_DEFAULT  (160)
#define DEVICE_CTUNE_DEFAULT     (160)
#define DEVICE_LFXO_CTUNE_DEFAULT (40)
#define IADC_TIMER_INTERVAL      (240)
#define APP_MAJOR_VERSION        (1)
#define APP_MINOR_VERSION        (1)
#define APP_STAGE_VERSION        (2) //max 255
#define SENSOR_VERSION           ((APP_MAJOR_VERSION << 16)|(APP_MINOR_VERSION<<8)|(APP_STAGE_VERSION))

#define PIR_TIMEROUT              (10)

static void setTxpowerDefaule(void);
static void setCtuneDefaule(void);
static void setLfxoCtuneDefaule(void);
static void gpio_state_change_handler(void);
static void SM_button_init(void);
static void SM_iadc_init(void);
static void printSoftWareInformation(void);
static void pir_interrupt_enable(bool enable);
static void wide_handler(void);
static uint8_t s_option[3] = {0};

#define PIR_2000_LUX

/**
 * @brief: 遥控器项目相关外设初始化
 * */
void SM_main(void)
{
  setTxpowerDefaule();
  setCtuneDefaule();
  setLfxoCtuneDefaule();
  SM_button_init();
  SM_iadc_init();
  startWatchDogTimer();
  printSoftWareInformation();
}

/**
 * @brief: 遥控器项目while函数相关处理
 * */
void SM_process(void)
{
  feedWatchDogHandler();
  SM_key_value_handler();
  gpio_state_change_handler();
  wide_handler();
}

/******************get device sleep state***************************/

bool device_sleep_state_get(void)
{
  return true;
}

/**************** set tx power/ctune defaule***********************/
static void setTxpowerDefaule(void)
{
  int16_t txPowerDeciDbm = 0;
  int ret = getThisParam(RfTxPower, &txPowerDeciDbm);
  if(ret != 0) {
      txPowerDeciDbm = DEVICE_TX_POWER_DEFAULT;
      setThisParam(RfTxPower, &txPowerDeciDbm);
  }
  RAIL_Status_t status = bsp_rf_set_tx_power_bdm(txPowerDeciDbm);
  if (status != RAIL_STATUS_NO_ERROR) {
      DS_app_log_error("set tx power error, status = 0x%x\r\n", status);
  }
}

static void setCtuneDefaule(void)
{
  uint32_t ctune = 0;
  int ret = getThisParam(RfCtune, &ctune);
  if(ret != 0) {
      ctune = DEVICE_CTUNE_DEFAULT;
      setThisParam(RfCtune, &ctune);
  }
  RAIL_Status_t status = bsp_rf_set_ctune(ctune);
  if (status != RAIL_STATUS_NO_ERROR) {
      DS_app_log_error("set ctune error, status = 0x%x\r\n", status);
  }
}

static void setLfxoCtuneDefaule(void)
{
  uint8_t ctune = 0;
  int ret = getThisParam(lfxoCtune, &ctune);
  if(ret != 0) {
      ctune = DEVICE_LFXO_CTUNE_DEFAULT;
      setThisParam(lfxoCtune, &ctune);
  }
  CMU_OscillatorTuningSet(cmuOsc_LFXO,ctune);
}

/************************button handler****************************/

static struct Button btn[2] = {0};
static MultiTimer buttonTimer[5] = {
    {.Handle = 0},
    {.Handle = 1},
    {.Handle = 2},
    {.Handle = 3},
    {.Handle = 4},
};
static uint16_t pirFallCnt = 0x00;
static uint16_t pirInvalidCnt = 0x02;
static uint32_t pirInvalidTime = 20;
static bool pirState = false;

void pirInvalidCntSet(uint16_t cnt)
{
  pirInvalidCnt = cnt;
}

void pirInvalidTimeSet(uint32_t times)
{
  pirInvalidTime = times;
}

static void ds_btn_state_change_callback(uint8_t intNo, void *ctx);

static ds_button_t button[5] = {
    {
        .port = gpioPortA,
        .pin = 5,
        .mode = gpioModeInput,
        .initial = 1,
        .valid = 0,
        .ds_button_state_change = ds_btn_state_change_callback,
    },
    {
        .port = gpioPortA,
        .pin = 7,
        .mode = gpioModeInput,
        .initial = 1,
        .valid = 0,
        .ds_button_state_change = ds_btn_state_change_callback,
    },
    {
        .port = gpioPortA,
        .pin = 0,
        .mode = gpioModeInput,
        .initial = 0,
        .valid = 1,
        .ds_button_state_change = ds_btn_state_change_callback,
    },
    {
        .port = gpioPortB,
        .pin = 1,
        .mode = gpioModeInput,
        .initial = 1,
        .valid = 0,
        .ds_button_state_change = ds_btn_state_change_callback,
    },
    {
        .port = gpioPortA,
        .pin = 6,
        .mode = gpioModeInput,
        .initial = 0,
        .valid = 1,
        .ds_button_state_change = ds_btn_state_change_callback,
    },
};

/**
 * @brief: button timer callback,每10ms轮询一次button状态
 * */
keyValue_t outputKeyValue = {0x00};
static bool pirAlarmState = false;

static void buttonTimerCallback(MultiTimer* timer, void *userData)
{
  (void)userData;
  uint8_t data[5] = {15,0,0,0,1};

  if(timer->Handle == 0) {
      button_handler(&btn[0]);
  }
  else if(timer->Handle == 1) {
      button_handler(&btn[1]);
  }
  else if(timer->Handle == 2) {
#ifdef PIR_2000_LUX
      pirFallCnt = 0;
      if(pirState == false) {
          pir_interrupt_enable(true);
      }
#else
      leTimerInterruptStop();
      iadc_scan_stop();
#endif
  }
  else if(timer->Handle == 3) {
      if((s_option[2]&0x01) == 0x01) {
          outputKeyValue.value[0] = 0;
          if(read_button_level(&button[3]) == button[3].valid) {
              outputKeyValue.value[1] = 0;
          }
          else {
              outputKeyValue.value[1] = 1;
              SM_led_start(data, ALARM_BLINK);
          }
          set_key_value(&outputKeyValue);
      }
      if(false == device_test_sleep_state_get()) {
          if(read_button_level(&button[3]) == button[3].valid) {
              DS_app_log_error("temple = 0x00 \r\n");
          }
          else {
              DS_app_log_error("temple = 0x01 \r\n");
          }
      }
  }
  else if(timer->Handle == 4) {
      pirAlarmState = true;
  }
}
static uint32_t raisRtc[2] = {0};
static uint32_t wide[2] = {0};
static bool upState[2] = {false};
static uint8_t adcState = 0x00;
/**
 * @brief:button 1 引脚状态改变时启动button timer
 * */
static void wide_handler(void)
{
  uint8_t data[5] = {15,0,0,0,1};
  for(uint8_t i=0;i<2;i++) {
      if(wide[i] > 0) {
          DS_app_log_error("W[%d]:%ld ms\r\n", i, wide[i]);
          if(wide[i] > pirInvalidTime) {
              pirFallCnt ++;
              if(pirFallCnt == pirInvalidCnt && pirAlarmState == true) {
                  pir_interrupt_enable(false);
                  upState[0] = false;
                  upState[1] = false;
                  softwareMultiTimerStop(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &buttonTimer[2], 0);
                  softwareMultiTimerStart(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &buttonTimer[2], 4*32768, buttonTimerCallback,NULL,0);
                  outputKeyValue.value[0] = 1;
                  set_key_value(&outputKeyValue);
                  SM_led_start(data, ALARM_BLINK);
                  wide[i^1] = 0;
                  if(false == device_test_sleep_state_get()) {
                      DS_app_log_error("pir test \r\n");
                  }
              }
              else if(pirFallCnt == pirInvalidCnt && pirAlarmState == false) {
                  pirAlarmState = true;
                  pirFallCnt = 0;
                  upState[0] = false;
                  upState[1] = false;
                  wide[i^1] = 0;
              }
          }
          wide[i] = 0;
      }
  }
}

static void ds_btn_state_change_callback(uint8_t intNo, void *ctx)
{
  (void)intNo;
  ds_button_t *btnDrive = (ds_button_t *)ctx;

  if(btnDrive->port ==  button[0].port && btnDrive->pin ==  button[0].pin && buttonTimer[0].status == EN_MULTITIMER_STATUS_IDLE) {
      button_handler(&btn[0]);
  }
  else if(btnDrive->port ==  button[1].port && btnDrive->pin ==  button[1].pin && buttonTimer[1].status == EN_MULTITIMER_STATUS_IDLE) {
      button_handler(&btn[1]);
  }
  else if(btnDrive->port == button[2].port && btnDrive->pin == button[2].pin) {
      if(read_button_level(&button[2]) == button[2].valid) {
#ifdef PIR_2000_LUX
          upState[0] = true;
          raisRtc[0] = READ_SYS_RTC_COUNT();
          if(buttonTimer[2].status == EN_MULTITIMER_STATUS_IDLE) {
              softwareMultiTimerStart(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &buttonTimer[2], PIR_TIMEROUT*32768, buttonTimerCallback,NULL,0);
          }
#else
          if(buttonTimer[2].status == EN_MULTITIMER_STATUS_IDLE) {
              initIADC(iadcPosInputPortCPin6, iadcPosInputPortCPin7);
              initLETIMER();
          }
          softwareMultiTimerStop(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &buttonTimer[2], 0);
          softwareMultiTimerStart(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &buttonTimer[2], 6653, buttonTimerCallback,NULL,0);
#endif
      }
#ifdef PIR_2000_LUX
      else {
          if(upState[0]) {
              upState[0] = false;
              wide[0] = (READ_SYS_RTC_COUNT()-raisRtc[0])*1000/32768;
              raisRtc[0] = 0;
          }
      }
#endif
  }
  else if(btnDrive->port == button[3].port && btnDrive->pin == button[3].pin && buttonTimer[3].status == EN_MULTITIMER_STATUS_IDLE) {
      softwareMultiTimerStart(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &buttonTimer[3], 983, buttonTimerCallback,NULL,0);
  }
  else if(btnDrive->port == button[4].port && btnDrive->pin == button[4].pin) {
      if(read_button_level(&button[4]) == button[4].valid) {
#ifdef PIR_2000_LUX
          upState[1] = true;
          raisRtc[1] = READ_SYS_RTC_COUNT();
          if(buttonTimer[2].status == EN_MULTITIMER_STATUS_IDLE) {
              softwareMultiTimerStart(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &buttonTimer[2], PIR_TIMEROUT*32768, buttonTimerCallback,NULL,0);
          }
#else
          if(buttonTimer[2].status == EN_MULTITIMER_STATUS_IDLE) {
              initIADC(iadcPosInputPortCPin6, iadcPosInputPortCPin7);
              initLETIMER();
          }
          softwareMultiTimerStop(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &buttonTimer[2], 0);
          softwareMultiTimerStart(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &buttonTimer[2], 6653, buttonTimerCallback,NULL,0);
#endif
      }
#ifdef PIR_2000_LUX
      else {
          if(upState[1]) {
              upState[1] = false;
              wide[1] = (READ_SYS_RTC_COUNT()-raisRtc[1])*1000/32768;
              raisRtc[1] = 0;
          }
      }
#endif
  }
}

/**
 * @brief: 读取button引脚状态
 * @param： button id
 * @return： gpio 状态
 * */
static uint8_t read_button_GPIO(uint8_t button_id)
{
  // you can share the GPIO read function with multiple Buttons
  switch(button_id)
  {
    case 0:
      return read_button_level(&button[0]);
      break;
    case 1:
      return read_button_level(&button[1]);
      break;
    default:
      return 0;
      break;
  }
}

bool isBattVoltageHigh(void)
{
  return true;
}

static void btn_press_handler(void* butt)
{
  Button* btn = (Button*)butt;

  if(btn->button_id == 0) {
      if(btn->event == LONG_PRESS_START) {
          startCommissiongJoin(buttonTrigger, other_device);
      }
      else if(btn->event == SINGLE_CLICK) {
          if(false == device_test_sleep_state_get()) {
              DS_app_log_error("reg btn test \r\n");
          }
      }
  }
  else if(btn->button_id == 1) {
      if(btn->event == LONG_PRESS_START) {
          startCommissiongJoin(buttonTrigger, other_device);
      }
      else if(btn->event == SINGLE_CLICK) {
          if(false == device_test_sleep_state_get()) {
              DS_app_log_error("reg btn test \r\n");
          }
      }
  }
}

static void gpio_state_change_handler(void)
{
  if(read_button_level(&button[0]) == button[0].valid) {
      if(buttonTimer[0].status == EN_MULTITIMER_STATUS_IDLE) {
          button_handler(&btn[0]);
      }
  }
  if(read_button_level(&button[1]) == button[1].valid) {
      if(buttonTimer[1].status == EN_MULTITIMER_STATUS_IDLE) {
          button_handler(&btn[1]);
      }
  }
  if((s_option[2]&0x01) == 0x01 && read_button_level(&button[3]) != outputKeyValue.value[1]) {
      if(buttonTimer[3].status == EN_MULTITIMER_STATUS_IDLE) {
          softwareMultiTimerStart(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &buttonTimer[3], 983, buttonTimerCallback,NULL,0);
      }
  }
}

/**
 * @brief: button reed初始化；注册不同状态相关回调函数
 * */
static void SM_button_init(void)
{
  ds_button_init(&button[0]);
  ds_button_init(&button[1]);
  ds_button_init(&button[3]);

  if(getThisParam(ENpbyOption, s_option) != 0) {
      setThisParam(ENpbyOption, s_option);
  }

  outputKeyValue.id = 0x10;
  outputKeyValue.valueSize = 2;
  if((s_option[2]&0x01) == 0x01) {
      outputKeyValue.value[1] = read_button_level(&button[3]);
  } else {
      outputKeyValue.value[1] = 0x00;
  }
  uint8_t data[5] = {0, 3, 0, 0, 1};
  SM_led_start(data, POWER_ON_BLINK);

  softwareMultiTimerStart(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &buttonTimer[4], 30*32768, buttonTimerCallback,NULL,0);
  if(false == device_test_sleep_state_get()) {
      pir_interrupt_enable(true);
  }

  button_init(&btn[0], &buttonTimer[0], buttonTimerCallback, read_button_GPIO, button[0].valid, 0);
  button_attach(&btn[0], LONG_PRESS_START, btn_press_handler);
  button_attach(&btn[0], SINGLE_CLICK, btn_press_handler);

  button_init(&btn[1], &buttonTimer[1], buttonTimerCallback, read_button_GPIO, button[1].valid, 1);
  button_attach(&btn[1], LONG_PRESS_START, btn_press_handler);
  button_attach(&btn[1], SINGLE_CLICK, btn_press_handler);
}

/************************led init***************************************/

static MultiTimer ledTimer;
static led_ins_t ledDriver = {0x00};

static ds_gpio_t led[3] = {
  {
      .port = gpioPortC,
      .pin = 2,
      .mode = gpioModePushPull,
      .initial = 1,
      .valid = 0,
  },
  {
      .port = gpioPortC,
      .pin = 1,
      .mode = gpioModePushPull,
      .initial = 1,
      .valid = 0,
  },
  {
      .port = gpioPortC,
      .pin = 3,
      .mode = gpioModePushPull,
      .initial = 1,
      .valid = 0,
  },
};

/**
 * @brief: led闪烁开始
 * @param： led物模型指针；5Bytes：R G Bbitmask bitTime cycleTimes
 * */
void SM_led_start(uint8_t *data, blinkType_t type)
{
  led_driver_init(&ledDriver, &ledTimer, led[0], led[1], led[2], data, type);
}

/*******************PIR enable*********************************/
static void pir_interrupt_enable(bool enable)
{
  DS_app_log_error("int = 0x%02x \r\n", enable);
  pirFallCnt = 0;
  if(enable) {
      pirState = true;
      ds_button_init(&button[2]);
      ds_button_init(&button[4]);
  }
  else {
      pirState = false;
      ds_button_deinit(&button[2]);
      ds_button_deinit(&button[4]);
  }
}

void pir_interrupt_test_enable(uint8_t enable)
{
  if(enable) {
      pir_interrupt_enable(true);
  }
  else {
      softwareMultiTimerStop(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &buttonTimer[2], 0);
      pir_interrupt_enable(false);
  }
}

/*****************key value handler*************************/

void recv_option_key_value_handler(uint8_t *option)
{
  uint8_t cnt;
  if(option[0] != s_option[0] || option[1] != s_option[1] || option[2] != s_option[2]) {
      setThisParam(ENpbyOption, option);
      //设置PIR探测灵敏度
#if 0
      if(((option[0]&0x0c) >> 2) == 0x00){
          pirInvalidCntSet(2);//自动灵敏度
      }else if(((option[0]&0x0c) >> 2) == 0x01){
          pirInvalidCntSet(8);//低灵敏度
      }else if(((option[0]&0x0c) >> 2) == 0x10){
          pirInvalidCntSet(5);//中灵敏度
      }else if(((option[0]&0x0c) >> 2) == 0x11){
          pirInvalidCntSet(2);//高灵敏度
      }
#else
      if(((option[0]&0xfc) >> 2) == 0x0000){
          cnt = 2;
      }else{
          cnt = ((option[0]&0xfc) >> 2);
      }
      pirInvalidCntSet(cnt);
#endif
      //判断防拆开关使能
      if((option[2]&0x01) == 0x01 && (s_option[2]&0x01) == 0x00) {
          outputKeyValue.value[1] = read_button_level(&button[3]);
          if(outputKeyValue.value[1] == 0x01) {
              set_key_value(&outputKeyValue);
          }
      }
      else if((option[2]&0x01) == 0x00 && (s_option[2]&0x01) == 0x01) {
          outputKeyValue.value[1] = 0x00;
      }
      memcpy(s_option, option, 3);
  }
}

/*******************battery detect***************************/

static MultiTimer iadcTimer;

static void iadcTimerCallback(MultiTimer* timer, void *userData)
{
  (void)timer;
  (void)userData;

  if(adcState == 0) {
#ifdef PIR_2000_LUX
      battery_detect_start(iadcPosInputAvdd);
#else
      initIADC(iadcPosInputPortCPin6, iadcPosInputPortCPin7);
#endif
      adcState = 0x01;
      softwareMultiTimerStart(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &iadcTimer, 32768*IADC_TIMER_INTERVAL, iadcTimerCallback,NULL,0);
  }
  else if(adcState == 0x01) {
      adcState = 0x00;
      SM_iadc_init();
  }
}

/**
 * @brief: adc init
 * */
static void SM_iadc_init(void)
{
  softwareMultiTimerStart(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &iadcTimer, 3277, iadcTimerCallback,NULL,0);
}

/**
 * @brief: 获取电压值
 * @return: battery unit:mV
 * */
uint8_t SM_battery_get(void)
{
  uint16_t battery = get_battery_monitor_voltage();
  if(false == device_test_sleep_state_get()) {
      DS_app_log_error("battery = %d \r\n", battery);
  }
  return battery>1800?(battery/10 - 180):0;
}
/************************temperature get*************************************/

/**
 * @brief: Get the internal temperature of the chip
 * @return: temperature
 * */
int8_t SM_tempDrv_get(void)
{
  float tempCelsius;
  int8_t result;

  tempCelsius = EMU_TemperatureGet();

  if (tempCelsius < INT8_MIN) {
    tempCelsius = INT8_MIN;
  } else if (tempCelsius > INT8_MAX) {
    tempCelsius = INT8_MAX;
  }

  // adding extra 0.5 before truncating to simulate rounding behavior
  result = (((int8_t) (tempCelsius + 0.5 - INT8_MIN)) + INT8_MIN);

  return result;
}

/**********************get hard information***************************/

/**
 * @brief: get hard information
 * @param: point
 * @return: value length
 * */
uint8_t get_hard_information(uint8_t *data)
{
  hardinfo_t hardInfo = {0x00};
  char psn[16] = "DJ0280N00001";
  int ret = 0;

  ret = getThisParam(ENpbyKeyM, hardInfo.psn);
  if(ret != 0) {
      memcpy(hardInfo.psn, psn, sizeof(psn));
      setThisParam(ENpbyKeyM, hardInfo.psn);
  }

  ret = getThisParam(ENbyDeviceType, &hardInfo.deviceType);
  if(ret != 0) {
      hardInfo.deviceType = EN_DEVICE_TYPE_IO_PIR;
      setThisParam(ENbyDeviceType, &hardInfo.deviceType);
  }

  ret = getThisParam(ENbyModelType, &hardInfo.modelType);
  if(ret != 0) {
      hardInfo.modelType = 0x01;
      setThisParam(ENbyModelType, &hardInfo.modelType);
  }

  ret = getThisParam(ENbyHardType, &hardInfo.hardType);
  if(ret != 0) {
      hardInfo.hardType = 0x01;
      setThisParam(ENbyHardType, &hardInfo.hardType);
  }

  ret = getThisParam(ENpbyMacID, hardInfo.pmacID);
  if(ret != 0) {
      getMacAddr(hardInfo.pmacID);
      setThisParam(ENpbyMacID, hardInfo.pmacID);
  }

  ret = getThisParam(ENpbyRfVer, hardInfo.pRfVer);
  if(ret != 0
      || hardInfo.pRfVer[0] != MAJOR_VERSION
      || hardInfo.pRfVer[1] != MINOR_VERSION
      || hardInfo.pRfVer[2] != STAGE_VERSION) {
      hardInfo.pRfVer[0] = MAJOR_VERSION;
      hardInfo.pRfVer[1] = MINOR_VERSION;
      hardInfo.pRfVer[2] = STAGE_VERSION;
      setThisParam(ENpbyRfVer, hardInfo.pRfVer);
  }

  ret = getThisParam(ENpbySensorVer, &hardInfo.sensorVer);
  if(ret != 0
      || hardInfo.sensorVer[0] != APP_MAJOR_VERSION
      || hardInfo.sensorVer[1] != APP_MINOR_VERSION
      || hardInfo.sensorVer[2] != APP_STAGE_VERSION) {
      hardInfo.sensorVer[0] = APP_MAJOR_VERSION;
      hardInfo.sensorVer[1] = APP_MINOR_VERSION;
      hardInfo.sensorVer[2] = APP_STAGE_VERSION;
      setThisParam(ENpbySensorVer, &hardInfo.sensorVer);
  }

  memcpy(data, &hardInfo, sizeof(hardInfo));

  return sizeof(hardInfo);
}

/**********************print informatio**************************/
static void printSoftWareInformation(void)
{
  uint8_t macAddr[8] = {0x00};
  getMacAddr(macAddr);
  int16_t txPowerDeciDbm = 0;
  uint32_t ctune = 0;
  char reason[12] = {0};
  uint8_t lfxoTune= 0;

  APP_PRINTF("\r\n*************information***************\r\n");
  uint32_t rst_cause = ds_rmu_init();
  resetToString(rst_cause, reason);
  APP_PRINTF("reset reason   : %s\r\n",reason);
  APP_PRINTF("device mac     : ");
  for(uint8_t i=0;i<7;i++){
      APP_PRINTF("%02x:", macAddr[i]);
  }
  APP_PRINTF("%02x \r\n", macAddr[7]);
  APP_PRINTF("stack version  : v%d.%d.%d \r\n", (STACK_VERSION>>16&0xFF), (STACK_VERSION>>8&0xFF),STACK_VERSION&0xFF);
  APP_PRINTF("app  version   : v%d.%d.%d \r\n", (SENSOR_VERSION>>16&0xFF), (SENSOR_VERSION>>8&0xFF),SENSOR_VERSION&0xFF);
  APP_PRINTF("git  version   : 0x%x\r\n", GIT_VERSION);
  APP_PRINTF("SN number      : %s\r\n", "SM_pir");
  APP_PRINTF("device type    : 0x%02X\r\n", EN_DEVICE_TYPE_IO_PIR);
  printfDeviceRfFreqInfo();
  getThisParam(RfTxPower, &txPowerDeciDbm);
  APP_PRINTF("device power   : %d \r\n", txPowerDeciDbm);
  getThisParam(RfCtune, &ctune);
  APP_PRINTF("device ctune   : %ld \r\n", ctune);
  getThisParam(lfxoCtune, &lfxoTune);
  APP_PRINTF("device lfxoTune: %d \r\n", lfxoTune);
  APP_PRINTF("build app time : %s %s \r\n", __DATE__, __TIME__);
#ifdef  CONFIG_JENKINS_BUILD_NUMBER
  APP_PRINTF("jenkins build number : %d\r\n", CONFIG_JENKINS_BUILD_NUMBER);
#else
  APP_PRINTF("jenkins build number : 0\r\n");//没定义默认0
#endif
  APP_PRINTF("***************************************\r\n\r\n");
}

/***********************get model api******************************/

static uint8_t device_input_output_state_get(uint8_t *buffer)
{
  buffer[0] = 0x00;
  buffer[1] = outputKeyValue.value[1];

  return 2;
}

uint8_t get_device_state(uint8_t *buffer)
{
  uint8_t data[8] = {0x00};
  uint8_t data_size = 0x00;
  uint8_t index = 0;

  buffer[index] = 0x10;
  index += 1;
  data_size = device_input_output_state_get(data);
  memcpy(&buffer[index], data, data_size);
  memset(data, 0, data_size);
  index += data_size;

  return index;
}

static QRFH1_t globalQrfH1 = {0};
static MultiTimer findMeTimer;

static void findMeTimerCallback(MultiTimer* timer, void *userData)
{
  (void)timer;
  (void)userData;
  uint8_t data[5] = {0};
  SM_led_start(data, NONE_BLINK);
}

void SM_device_QRF_state_Handle(QRFH1_t qrfH1, QRFH2_t qrfH2)
{
  uint8_t data[5] = {0};
  if(qrfH2.isFM == 1) {
      data[1] = 15;
      data[3] = 1;
      data[4] = 15;
      SM_led_start(data, FIND_ME_BLINK);
      softwareMultiTimerStop(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &findMeTimer,0);
      softwareMultiTimerStart(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &findMeTimer, 32768*30, findMeTimerCallback,NULL,0);
  }
  else {
      if(findMeTimer.status != EN_MULTITIMER_STATUS_IDLE)
        SM_led_start(data, NONE_BLINK);
  }
  if(qrfH1.IOen != globalQrfH1.IOen) {
      if(qrfH1.IOen == 1) {
          pir_interrupt_enable(true);
      }
      else {
          softwareMultiTimerStop(EN_LP_HARD_TIMER_EM3_SYS_RTC_1, &buttonTimer[2], 0);
          pir_interrupt_enable(false);
      }
      globalQrfH1.IOen = qrfH1.IOen;
  }
}
/**********************set gpio mode default*************************/

void staticPowerGpioInit(void)
{
#if 1
  CMU_ClockEnable(cmuClock_GPIO, true);
  GPIO_PinModeSet(gpioPortA, 3,gpioModePushPull,1);
  GPIO_PinModeSet(gpioPortA, 4,gpioModeInputPull,0);
  GPIO_PinModeSet(gpioPortB, 0,gpioModeInputPull,1);
#else
  CMU_ClockEnable(cmuClock_GPIO, true);
  GPIO_PinModeSet(gpioPortA, 0,gpioModeInputPull,1);
  GPIO_PinModeSet(gpioPortA, 3,gpioModePushPull,0);
  GPIO_PinModeSet(gpioPortA, 4,gpioModeInputPull,0);
  GPIO_PinModeSet(gpioPortA, 5,gpioModeInputPull,1);
  GPIO_PinModeSet(gpioPortA, 6,gpioModeDisabled,0);
  GPIO_PinModeSet(gpioPortA, 7,gpioModeInputPull,1);
  GPIO_PinModeSet(gpioPortA, 8,gpioModeDisabled,0);
  GPIO_PinModeSet(gpioPortB, 0,gpioModeInputPull,1);
  GPIO_PinModeSet(gpioPortB, 1,gpioModeInputPull,1);
  GPIO_PinModeSet(gpioPortC, 0,gpioModeDisabled,0);
  GPIO_PinModeSet(gpioPortC, 1,gpioModePushPull,1);
  GPIO_PinModeSet(gpioPortC, 2,gpioModePushPull,1);
  GPIO_PinModeSet(gpioPortC, 3,gpioModePushPull,1);
  GPIO_PinModeSet(gpioPortC, 4,gpioModePushPull,0);
  GPIO_PinModeSet(gpioPortC, 5,gpioModeDisabled,0);
  GPIO_PinModeSet(gpioPortC, 6,gpioModeDisabled,0);
  GPIO_PinModeSet(gpioPortC, 7,gpioModeDisabled,0);
  GPIO_PinModeSet(gpioPortD, 2,gpioModeDisabled,0);
  GPIO_PinModeSet(gpioPortD, 3,gpioModeDisabled,0);
#endif
}

#endif

